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The unsteady overtopping of barriers by gravity currents and dam-break flows

Skevington, Edward W.G.; Hogg, Andrew J.

Authors

Andrew J. Hogg



Abstract

The collision of a gravitationally driven horizontal current with a barrier following release from a confining lock is investigated using a shallow water model of the motion, together with a sophisticated boundary condition capturing the local interaction. The boundary condition permits several overtopping modes: supercritical, subcritical and blocked flow. The model is analysed both mathematically and numerically to reveal aspects of the unsteady motion and to compute the proportion of the fluid trapped upstream of the barrier. Several problems are treated. Firstly, the idealised problem of a uniform incident current is analysed to classify the unsteady dynamical regimes. Then, the extreme regimes of a very close or distant barrier are tackled, showing the progression of the interaction through the overtopping modes. Next, the trapped volume of fluid at late times is investigated numerically, demonstrating regimes in which the volume is determined purely by volumetric considerations, and others where transient inertial effects are significant. For a Boussinesq gravity current, even when the volume of the confined region behind the barrier is equal to the fluid volume, 30% of the fluid escapes the domain, and a confined volume three times larger is required for the overtopped volume to be negligible. For a subaerial dam-break flow, the proportion that escapes is in excess of 60% when the confined volume equals the fluid volume, and a barrier as tall as the initial release is required for negligible overtopping. Finally, we compare our predictions with experiments, showing a good agreement across a range of parameters.

Citation

Skevington, E. W., & Hogg, A. J. (2023). The unsteady overtopping of barriers by gravity currents and dam-break flows. Journal of Fluid Mechanics, 960, Article A27. https://doi.org/10.1017/jfm.2023.187

Journal Article Type Article
Acceptance Date Feb 24, 2023
Online Publication Date Apr 5, 2023
Publication Date Apr 10, 2023
Deposit Date Apr 20, 2023
Publicly Available Date Oct 6, 2023
Journal Journal of Fluid Mechanics
Print ISSN 0022-1120
Publisher Cambridge University Press
Peer Reviewed Peer Reviewed
Volume 960
Article Number A27
DOI https://doi.org/10.1017/jfm.2023.187
Keywords Mechanical Engineering; Mechanics of Materials; Condensed Matter Physics; Applied Mathematics
Public URL https://hull-repository.worktribe.com/output/4267100
Additional Information Copyright: © The Author(s), 2023. Published by Cambridge University Press

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Copyright Statement
This article has been published in a revised form in Journal of Fluid Mechanics: https://doi.org/10.1017/jfm.2023.187. This version is free to view and download for private research and study only. Not for re-distribution, re-sale or use in derivative works. © The authors.





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